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Review of Literature
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Depression is a state of low mood and aversion to activity that affects person's
thoughts, behavior, feelings and physical well-being. Depressed people feel sad,
anxious, empty, hopeless, helpless, worthless, guilty, irritable, or restless. They may
lose interest in activities that once were pleasurable, experience loss of appetite or
overeating, or problems concentrating, remembering details or making decisions; and
may contemplate or attempt suicide. Insomnia, excessive sleeping, fatigue, loss of
energy, or aches, pains or digestive problems that are resistant to treatment may be
present (Zimmerman, 2004). Depressed mood is not necessarily a psychiatric
disorder. Depressed mood is a normal reaction to certain life events, a symptom of
some medical conditions, and side-effect of some medical treatments. Depressed
mood is also a main or common feature of certain psychiatric syndromes such as
clinical depression (Mc-Pherson and Martin, 2010).
Depressed mood can be the result of a number of infectious diseases and
physiological problems including Addison's disease, Lyme disease, multiple sclerosis,
sleep apnea and disturbed circadian rhythm. It is often one of the early symptoms of
hypothyroidism (reduced activity of the thyroid gland). A number of psychiatric
syndromes feature depressed mood as a main symptom. The mood disorders are a
group of disorders considered to be primary disturbances of mood. These include
major depressive disorder (MDD), commonly called major depression or clinical
depression, where a person has at least two weeks of depressed mood or a loss of
interest or pleasure in nearly all activities; and dysthymia, a state of chronic depressed
mood, the symptoms of which do not meet the severity of a major depressive episode.
Another mood disorder, bipolar disorder, features one or more episodes of abnormally
elevated energy levels, cognition and mood, but may also involve one or more
depressive episodes. Outside the mood disorders, borderline personality disorder
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commonly features depressed mood, and adjustment disorder with depressed mood is
a mood disturbance appearing as a psychological response to an identifiable event or
stressor, in which the resulting emotional or behavioral symptoms are significant but
do not meet the criteria for a major depressive episode (APA, 2000)
PREVALENCE
Centers for Disease Control and Prevention analysis of Behavioral Risk Factor
Surveillance System survey data from 2006 and 2008 found nine percent of 2,35,067
adults surveyed in 45 states, District of Columbia, Puerto Rico, and US Virgin Islands
3.4% met the criteria for current depression (defined as meeting criteria for either
major depression or "other depression" during the 2 weeks preceding the survey). By
state, age-standardized estimates for current depression ranged from 4.8% in North
Dakota to 14.8% in Mississippi according to Centre for disease control and
Prevention, 2010.
ETIOLOGY
The specific cause of major depressive disorder is not known. As with most
psychiatric disorders, major depressive disorder appears to be multifactorial in its
origin. According to the American Academy of Child and Adolescent Psychiatry
(AACAP) practice parameters for depressive disorders in childhood and adolescence,
a history of a previous depressive episode, subsyndromal symptoms of depression,
dysthymia, and anxiety disorders increase the risk for future depression. Symptoms of
major depression in adolescence strongly predicted adult episodes of major depression
in a study of an epidemiologic sample of 776 adolescents by Pine and associates (Pine
et al., 1999).
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Genetics
Genetic susceptibility plays a role in the development of major depressive
disorder. Individuals with a family history of affective disorders (7%), panic disorder,
and alcohol dependence (8%) carry a higher risk for major depressive disorder.
Studies such as those reported by Akiskal and Weller, (1989) and Weissman et al.,
(1984) suggest a genetic component in the etiology of depressive disorders. Nobile et
al., (1999) found that human platelet 5-HT (5-hydroxy tryptamine) uptake is
differentially influenced in children with and without depression by a common
genetic variant of the promoter region of 5-HT. Birmaher et al., (1997) found that,
before onset of affective illness, children who were at high risk had the same pattern
of neuroendocrine response to 5-hydroxy-L-tryptophan (L-5-HTP) challenge as did
children with major depression. These findings could constitute the identification of a
trait marker for depression in children.
Some evidence suggests that late-onset depression (after age 60 years) is an
etiologically and clinically distinct syndrome (Blazer, 2003) and that genetic factors
play less of a role in late-onset than early-onset depression. A family history of
depression is less common among older adults with depression than younger adults.
However, certain genetic markers have been, although inconsistently, associated with
late-onset depression, including polymorphisms of the apolipoprotein E, brain derived
neutropic factor (BDNF), and 5-hydroxy tryptamine transporter genes. Interestingly,
these markers have also been associated with cognitive impairment, hippocampal
volume, and antidepressant response, respectively.
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Stressors
Although major depressive disorder can arise without any precipitating
stressors, stress and interpersonal losses certainly increase risk. Psychodynamic
formulations found that significant losses in early life predispose to major depressive
disorder over the lifespan of the individual, as does trauma, either transient or chronic.
Depression is a behavioral response to repeated stressors and cognitive distortions (ie,
negative thoughts) contribute to and perpetuate depressed mood.
Chronic pain,
medical illness, and psychosocial stress also play a role in both the initiation and
maintenance of major depressive disorder. Older adults may perceive medical illness
as psychologically distressing, and these illnesses may lead to increased disability,
decreased independence, and disruption of social networks (Bruce, 2002). Other
psychosocial risk factors for depression in late life include the following (Ohara et al.,
1984):
Impaired social supports
Caregiver burden
Loneliness
Bereavement
Negative life events
In addition, neurochemical hypotheses point to the deleterious effects of
cortisol and other stress-related substances on the neuronal substrate of mood in the
central nervous system (CNS). Exposure to certain pharmacologic agents also
increases the risk of depression; medications such as reserpine or beta-blockers, as
well as abused substances such as cocaine, amphetamine, narcotics, and alcohol, are
associated with higher rates of major depressive disorder. A meta-analysis that
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included all relevant studies exploring the interaction between a serotonin transporter
promoter polymorphism (5-HTTLPR) and stress in the development of depression
suggested that 5-HTTLPR moderates the relationship between stress and depression
(Karg et al., 2011).
Neuroendocrine abnormalities and neurodegenerative diseases
Prepubertal children who were depressed had lower cortisol secretion during
the first 4 hours of sleep than did children in the control group, according to De-Bellis
et al., (1996) who studied neuroendocrine changes in depressed prepubertal children.
The investigators examined nocturnal secretion of adrenocorticotropin (ACTH),
cortisol, growth hormone (GH), and prolactin (PL) in the groups with depression and
control groups, ACTH, GH, and PL secretion did not differ between the two groups.
Possible abnormalities of the neurotransmitter systems remain under
investigation
Neurodegenerative diseases (especially Alzheimer disease and Parkinson
disease, stroke, multiple sclerosis, seizure disorders, cancer, macular degeneration,
and chronic pain have been associated with higher rates of depression (Krishnan,
2002).
Parent-child relations
The parent-child relation model conceptualizes depression as the result of poor
parent-child interaction. Adults with depression report low paternal involvement and
high maternal overprotection during early childhood. Troubled relationships with
parents, siblings, and peers are common in children and adolescents with affective
illness. A child who is affectively ill often has a parent who is affectively ill. It is not
uncommon for children to report abuse and/or neglect by parents who are affectively
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ill. Childhood abuse and neglect, as well as a cumulative load of stressors over a
lifetime, have both been associated with late-onset depression. Hammen et al., (1991)
reported a significant temporal association between mother and child. They found that
children with substantial stress exposure who also had symptomatic mothers were
significantly more depressed than children who were exposed to comparable levels of
stress only.
Vascular depression
The vascular depression hypothesis posits that cerebrovascular disease may
cause or contribute to late-life depression. Various lines of evidence support this
hypothesis, including the following (Thomas et al., 2004);
Higher incidence of depression following a stroke
Higher prevalence of ischemic white-matter changes in older adults with
depression than those without
Bidirectional association between depression and coronary artery disease
(CAD)
Higher rates of depression among patients with vascular dementia than those
with Alzheimer disease
EPIDEMIOLOGY
The lifetime incidence of major depressive disorder in the United States is
20% in women and 12% in men. The prevalence is as high as 10% in patients
observed in a medical setting. Klerman (1988) and Gershon et al., (1987)
reported a
progressive increase in the lifetime cases of major depression over the last 70 years,
with high rates of affective disorders among relatives and a younger age of onset in
successive cohorts. In 2010, the Center for Disease Control and Prevention (CDCP)
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released a report estimating the prevalence of current depression among adults during
2006-2008. Among 2,35,067 adults, 9% met the criteria for current depression,
including 3.4% who met the criteria for major depression. Internationally reported
adult prevalence rates of depression generally mirror those of the United States, and
estimates of prevalence of depression among community-dwelling elderly are
surprisingly consistent (eg, England, 2.9%; The Netherlands, 2.0%; Sweden, 5.6%;
Nigeria, 1.6%). However, sparse data are available on the international incidence of
major depression in children and adolescents.
Helgason examined the entire Icelandic birth cohort of 1895-97 with periodic
follow-up until cohort individuals reached age 74-76 years. The lifetime estimates of
risk for any affective disorder were 14.8% for females and 9.8% for males (Helgason,
1964). The World Health Organization (WHO) collaborative study on the assessment
of depressive disorders found considerable similarity in depressive symptomatology
across cultures in Canada, Iran, Japan, and Switzerland (Jablensky et al., 1981). The
Stirling County Study, which began shortly after World War II, offered a 40-year
perspective of the prevalence and incidence of psychiatric disorders among an adult
population in Atlantic Canada, in which the overall prevalence of depression
remained stable at 5% across 3 separate samples in 1952, 1970, and 1992. In the year
2000 sample, however, the prevalence had shifted from older to younger persons, and
the female-to-male ratio had increased (Murphy et al., 2000).
Copeland et al., (1999) found widely ranging prevalence’s for depression in
elderly persons in 9 European populations. The prevalence for females was higher
than that for males, and there was no constant association between prevalence and
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age. Meta-analysis revealed an overall prevalence of 12.3% and sex frequencies of
14.1% for females and 8.6% for males.
Children and adolescents
In prepubertal children, boys and girls were affected equally. Hankin et al.,
(1998) found that the most critical time for sex differences in depression is from age
15-18 years. During this period, the increase of the overall rates of depression and
onset of new cases of depression peak. The incidence of depression was 0.9% in
preschool-aged children, 1.9% in school-aged children, and 4.7% in adolescents in a
study by Kashani and Sherman, (1988). More than 22% of female high school
students and more than 11% of male high school students reported 1 current or
lifetime episode of unipolar depression in one study. In the same study, the percentage
of male students with 2 or more episodes of unipolar depression was 4.9%; it was
1.6% in female students (Lewinsohn et al., 1993).
Hispanic youths in Los Angeles country (aged 12-17 years) reported more
symptoms of depression, independent of socioeconomic status, when compared with
white, black, or Asian American adolescents, according to an epidemiologic study by
Siegel et al., (1998). This study also found significant effects of social class on
depression. As income decreased, the average level of depression increased. The 1-
year incidence of major depression was 3.3% in adolescents aged 11-16 years in the
southeastern United States (Garrison et al., 1997).
Elderly persons
Although rates of depression in women and men are highest in those aged 25-
44 years, the incidence of clinically significant depressive symptoms increases with
advancing age, especially when associated with medical illness or institutionalization.
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However, the depression might not meet criteria for major depression because of
somewhat atypical features of depression in elderly persons.
Minor depression and major depression
The prevalence of minor depression or subsyndromal depression is likely
higher than that of major depressive disorder; levels of functional impairment,
medical burden, and quality of life are lower than in major depressive disorder but
higher than in older adults without any depression (Arean and Cook, 2002).
PROGNOSIS
Major depressive disorder is a disorder with significant potential morbidity
and mortality, contributing as it does to suicide, medical illness, disruption in
interpersonal relationships, substance abuse, and lost work time. With appropriate
treatment, 70-80% of individuals with major depressive disorder achieve a significant
reduction in symptoms, although as many as 50% of patients may not respond to the
initial treatment trial. Forty percent of individuals with major depressive disorder
untreated at 1 year will continue to meet criteria for the diagnosis, whereas an
additional 20% will have a partial remission. Pretreatment of irritability and psychotic
like symptoms are associated with poorer outcomes. Partial remission and/or a history
of chronic major depressive disorders are risk factors for recurrent episodes and
treatment resistance.
Late-onset depression
The prognosis of late-onset depression is felt to be poorer in the elderly than in
younger patients, and it appears to be dependent on physical handicap or illness and
lack of social support. Of particular importance is the increasing risk of death by
suicide, particularly among elderly men. In older patients, depression is frequently
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comorbid with chronic medical conditions and can lead to worsening medical
outcomes, including mortality; patients with depression have higher usage of medical
services. For example, coronary artery disease is a risk factor for the development of
depression, and depression is an independent risk factor for the development of
coronary disease. Patients with both conditions are more likely to die than those with
coronary artery disease alone. Both behavioral and physiological explanations are
likely for these associations (Lesperance and Smith, 2007).
Millard suggested the "rule of thirds" concerning the prognosis of late-onset
depression, which states that regardless of treatment, approximately one third of
patients will manifest remission, another one third will remain symptomatic in the
same condition, and the remaining one third will worsen (Millard, 1983). In fact,
research has shown that approximately 60% of patients with late-onset depression will
have at least 1 recurrence, and up to 40% of these patients will have chronic or
continuously recurrent depression (Alexopoulos and Choster, 1992). Late-onset
depression has been reported to double the risk of developing mild cognitive
impairment (Geda et al., 2006) and the likelihood that the mild cognitive impairment
will develop into dementia (Modrego and Ferrandez, 2004). Compared with
participants without depression history, those with late-life depression reportedly have
increased all-cause dementia risk; however, early life depression had no association
with dementia risk (Li et al., 2011). Treating depression has been suggested to
possibly stunt progression to mild cognitive impairment and from there to dementia,
although there has been little evaluation of this hypothesis to date.
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Suicide
Depression plays a role in more than one half of all suicide attempts, whereas
the death rate from suicide among those with affective disorders exceeds 15%.
According to Centers for Disease Control and Prevention (CDC) data, suicide was the
eleventh leading cause of death in the United States in 2006, accounting for 33,300
deaths, and it continues to rank as the second leading cause of death in adolescents
and the third leading cause of death in people aged 15-24 years. However, despite
these data and the fact that depression is more often diagnosed in women, the highest
suicide rate is in men older than 75 years; more men than women die from suicide by
a factor of 4.5:1. White men complete more than 78% of all suicides, and 56% of
suicide deaths in males involve firearms. Poisoning is the predominant method among
females. In addition to older age and male sex, risk factors for suicide include the
following (Conwell et al., 2002; Elovainio et al., 2009):
Diagnosis of major depression
Previous history of suicide attempt
Burden of medical disease and presence of current serious medical condition
(although this risk may be mediated by a diagnosis of depression)
Recent stressful life events, especially family discard
Lack of social support
Being widowed or divorced
The presence of a gun in the home
Unexplained weight loss
The use of antidepressants may in fact be a protective factor (Friedman and
Leon, 2007).
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Studies also show that major depressive disorder contribute to higher mortality
and morbidity in the context of other medical illnesses, such as myocardial infarction,
and that successful treatment of the depressive episode improves medical and surgical
outcomes. Suicide rates among American Indian and Alaskan natives between ages 15
and 34 years are almost twice the national average for this age range. Hispanic
females make significantly more suicide attempts than their male or non-Hispanic
counterparts. In 2005, 1.4% of all deaths worldwide were attributed to suicide. The
real number is unknown, as underreporting is predictably significant. Suicide is
estimated to be the eighth leading cause of death in all age ranges. In Eastern Europe,
10 countries report more than 27 suicides per 1,00,000 persons. Latin America and
Muslim countries report the lowest rates, with fewer than 6.5 cases per 1,00,000.
PATHOPHYSIOLOGY OF DEPRESSION
The underlying pathophysiology of major depressive disorder has not been
clearly defined. Clinical and preclinical trials suggest a disturbance in central nervous
system (CNS) serotonin (5-HT) activity as an important factor. Other
neurotransmitters implicated include norepinephrine (NE) and dopamine (DA)
(Dunlop and Nemeroff, 2007).
The role of CNS 5-HT activity in the pathophysiology of major depressive
disorder is suggested by the efficacy of selective serotonin reuptake inhibitors (SSRIs)
in the treatment of major depressive disorder. Furthermore, studies have shown that
an acute, transient relapse of depressive symptoms can be produced in research
subjects in remission using tryptophan depletion, which causes a temporary reduction
in CNS 5-HT levels. Serotonergic neurons implicated in affective disorders are found
in the dorsal raphe nucleus, the limbic system, and the left prefrontal cortex. Seasonal
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affective disorder is a form of major depressive disorder that arises during the winter
and resolves during the spring and summer. Studies suggest that seasonal affective
disorder is also mediated by alterations in CNS levels of 5-HT and appears to be
triggered by alterations in circadian rhythm and sunlight exposure.
Vascular lesions contribute to depression by disrupting the neural networks
involved in emotion regulation in particular, fronto striatal pathways that link dorso
lateral prefrontal cortex, orbito frontal cortex, anterior cingulate, and dorsal cingulate
cortex (Alexopoulos, 2005). Other components of limbic circuitry, in particular the
hippocampus and amygdala, have been implicated in depression. Functional neuro
imaging studies support the hypothesis that the depressed state is associated with
decreased metabolic activity in neocortical structures and increased metabolic activity
in limbic structures (Mayberg et al., 1999). In recent years, an abnormality in an area
of the brain that helps to control emotional reactions has been found and contributes
to a new understanding of why persons develop depression and other affective
disturbances. By using positron emission tomographic (PET) images, researchers
found an area of the prefrontal cortex with an abnormally diminished activity in
patients with unipolar depression and bipolar depression. This region is related to
emotional response and has widespread connections with other areas of the brain.
These other areas are responsible for the regulation of DA, Noradrenaline (NA), and
5-HT, which have important roles in the regulation of mood.
An integrative model of late-onset depression states that age-related brain
changes and disease-related changes (eg, cerebrovascular disease), coupled with
physiologic vulnerabilities (eg, genetic risk factors, personal history of depression)
and psychosocial adversity, lead to disruptions in the functional circuitry of emotion
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regulation (namely, hypometabolism of cortical structures and hypermetabolism of
limbic structures), resulting in the clinical manifestations of depression (Alexopoulos,
2005). Endocrine changes in depression are evident across the life span, but some are
unique to aging. Women with a previous history of depression are at higher risk of
developing depression during menopause, suggesting a role for estrogen in mood
regulation; low testosterone levels have been associated with depression in older men.
Neurotransmitters and Mood
Neurotransmitters, especially noradrenaline, serotonin and dopamine are
believed to be key in the control of mood and emotional behavior.
1. Noradrenaline and the Noradrenergic System
The noradrenaline system is referred to as the noradrenergic system, and
receptors specific to noradrenaline or adrenaline are both referred to as adrenergic
receptors. Noradrenaline, which is synthesized from the dietary amino acid tyrosine,
is believed to play a major role in the control of mood and emotional behavior. The
major concentration of noradrenergic neurons is in the locus ceruleus in the
midbrain. The axons of these neurons project upward through the forebrain to the
cerebral cortex, the limbic system, the thalamus, and the hippocampus.
Noradrenaline, a key neurotransmitter involved in the control of mood and
emotional behavior, is believed to inhibit or stimulate a variety of emotional
responses such as anxiety, aggression, stress, and sleep patterns. Noradrenaline is
released by a presynapse, and binds to receptor sites on a postsynaptic neuron.
Residual noradrenaline (NE) is taken back up into the presynaptic neuron (reuptake)
where it is recycled into storage vesicles or metabolized by the enzyme monoamine
oxidase (MAO degradation).
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2. Serotonin and the Serotonergic System
Like noradrenaline, serotonin (5-HT) is a key neurotransmitter involved in the
control of mood. The axons of serotonergic neurons originate in the raphe nuclei of
the brain stem and project to the cerebral cortex, the limbic system, cerebellum, and
spinal cord. Serotonin is involved in the regulation of pain, pleasure, anxiety, panic,
arousal, and sleep behavior (the sleep-wake cycle). Serotonin (5-HT) is synthesized
from a dietary amino acid called tryptophan. Like noradrenaline, serotonin is a
neurotransmitter. As such, serotonin is released by a presynaptic neuron, travels
across a synapse, and binds to a receptor site in a postsynaptic neuron.
3. Neurotransmitter Receptor Sites
There are different types of neurotransmitters, there are different receptor
sites, each with an affinity for a specific neurotransmitter. In addition to the receptor
sites located on postsynaptic neurons in the brain, receptor sites exist on neurons in
other parts of the body, such as the gut or salivary glands. (The side effect profile of
antidepressant drugs varies with their affinity for these receptors). In recent years,
many subtypes of these receptors have been discovered. Some adrenergic receptors,
are now known to be associated with inhibitory processes while others are
stimulatory. While the science of mood disorders is still very incompletely
understood, some very useful theories have emerged over the past two decades.
Theories of Depression
The Biogenic Amine Hypothesis
The Receptor Sensitivity Hypothesis
The Serotonin-only Hypothesis
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The Permissive Hypothesis
The Electrolyte Membrane Hypothesis
The Neuroendocrine Hypothesis
The Biogenic Amine Hypothesis.
In the early 1950s, researchers noticed that drugs that decreased monoamines
precipitated depression, and drugs that increased monoamines relieved depression.
The Biogenic Amine Hypothesis states that depression is caused by a deficiency of
monoamines, particularly noradrenaline and serotonin. According to this hypothesis,
depression can be alleviated by drugs that increase the availability of noradrenaline
and serotonin. One method of increasing monoamines centers around the action of
monomaine oxidase (MAO). Blocking the action of MAO leads to an increased
availability of neurotransmitters. When the action of MAO is blocked,
neurotransmitters are not metabolised, so they accumulate in the presynaptic neuron.
Drugs which block the metabolism of noradrenaline and serotonin via inhibition of
MAO are called MAO inhibitors (MAOIs). MAOIs were among the first clinically
proven antidepressants. Taken chronically, MAOIs also produce desensitization and
down-regulation of postsynaptic receptors. Another way to increase monoamines
involve blocking the process of reuptake. Blocking reuptake prevents the presynaptic
neuron from reclaiming neurotransmitter, which increases the amount of
neurotransmitter in the synaptic cleft.
Drugs were developed in the 1950s that blocked reuptake in just this way.
These drugs - still widely used today - are called tricyclic antidepressants or TCAs.
The Biogenic Amine Hypothesis has been the cornerstone of research on depression
for more than 30 years. However, an important fact cannot be explained by the
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Biogenic Amine Hypothesis. TCAs and MAOIs increase available neurotransmitters
quite rapidly within a matter of hours. Yet, typically, clinical relief takes much
longer. A person suffering from depression may not experience significant relief for
as long as 6 to 8 weeks.
The Receptor Sensitivity Hypothesis
The Biogenic Amine Hypothesis alone cannot explain the delay in time of
onset of clinical relief of depression of up to 6-8 weeks. Supersensitivity is a
compensatory response of the postsynaptic neuron when it receives too little
stimulation. The neuron tries to make up for a lack of stimulation by increasing
receptor responsiveness. Over time, the postsynaptic neuron also compensate for lack
of stimulation by synthesizing additional receptor sites. This process is known as up-
regulation. By increasing the amount of neurotransmitter in the cleft, response is
normlised. Increased neurotransmitter increases stimulation of receptor sites, which
prompts the postsynaptic neuron to compensate by decreasing receptor sensitivity, a
process known as desensitization. The postsynaptic neuron is also thought to
compensate for increasing stimulation by decreasing the number of receptor sites, a
process known as down-regulation.
Antidepressant drugs are thought to work by increasing the amount of
neurotransmitters in the cleft. They do this by blocking metabolism of monoamines
the MAOIs or by blocking reuptake the TCAs. Most TCAs are more effective in
blocking noradrenaline reuptake than serotonin reuptake. Chronic administration of
TCAs or MAOIs is thought to alter the responsiveness and/or the number of
postsynaptic receptor sites. Observation of this long-term effect of antidepressants led
to the Receptor Sensitivity Hypothesis.
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This hypothesis proposes that depression is the result of a pathological
alteration (supersensitivity and up-regulation) in receptor sites, which results from too
little stimulation by monoamines, i.e., a deficiency of noradrenaline and serotonin in
the cleft. Chronic administration of TCAs or MAOIs results in increased availability
of noradrenaline and serotonin. This causes desensitization (the uncoupling of
receptor sites) and possibly down-regulation (a decrease in the number of receptor
sites). According to this hypothesis, relief from depression symptoms comes from a
normalization of receptor sensitivity.
According to the Receptor Sensitivity Hypothesis, antidepressant drugs
achieve their clinical effect by reducing receptor supersensitivity. This theory is an
important step toward understanding the long delay between administration of TCAs
and MAOIs and clinical response. While TCAs are effective in blocking the reuptake
of noradrenaline and serotonin into the presynaptic neuron, they are non-selective:
they also block postsynaptic receptor sites, including cholinergic (muscarinic),
histaminergic, and adrenergic receptor sites. Blockade of histaminergic receptors lead
to sedation, weight gain, and hypotension. In the elderly, this is a particular problem,
since it results in fainting or falls. TCAs also block muscarinic receptors, which lead
to blurred vision, dry mouth, constipation, urinary retention, confusion, and delirium.
The Serotonin-only Hypothesis
Early in the 1980s, drugs were introduced that selectively blocked serotonin
reuptake, resulting in more serotonin available in the cleft. These drugs were known
as selective serotonin reuptake inhibitors, or SSRIs. Unlike the TCAs, which are non-
selective, the SSRIs have fewer serious side effects and are therefore easier for
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patients to tolerate. This has led to the Serotonin-only Hypothesis which emphasizes
the role of serotonin in depression and downplays noradrenaline.
But the serotonin-only theory has shortcomings:
1. It does not explain why there is a delay in onset of clinical relief;
2. It does not explain the role of noradrenaline in depression.
A study at Yale tested the serotonin-only hypothesis and demonstrated the
importance of noradrenaline. The test group consisted of depressed patients who were
being treated successfully with either selective serotonin reuptake inhibitors (SSRIs)
or a non-selective TCA. All these patients were placed on a tryptophan-free diet.
Researchers reasoned that serotonin alone was responsible for depression, only those
patients taking SSRIs relapsed, while those on TCAs did not. This suggested that both
noradrenaline and serotonin play a critical role in depression. When noradrenergic
neurons are destroyed in laboratory animals, drugs that affect serotonin do not have
their usual effects. Likewise, when serotonergic neurons are destroyed, drugs that
affect noradrenaline do not have their usual effects.
The Permissive Hypothesis
Mood is controlled by a balance of noradrenaline and serotonin, not by
absolute levels of these neurotransmitters or their receptors. According to this
hypothesis - the Permissive Hypothesis - the control of emotional behavior results
from a balance between noradrenaline and serotonin. According to this theory, both
the manic phase and the depressive phase of bipolar disorder are characterized by low
central serotonin function. Evidence suggests that brain serotonin systems dampen or
inhibit a range of functions involving other neurotransmitters. Mood disorders result
from the removal of the serotonin damper. The Permissive Hypothesis postulates that
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low levels of serotonin permit abnormal levels of noradrenaline to cause depression or
mania. If serotonin cannot control noradrenaline, and noradrenaline falls to
abnormally low levels, the patient becomes depressed. On the other hand, if the level
of serotonin falls and the level of noradrenaline becomes abnormally high, the patient
becomes manic. According to this hypothesis, antidepressant drugs are effective to the
degree that they reinstate the ability of serotonin to control noradrenaline, thus
restoring the critical balance that controls emotional behavior.
A new class of antidepressant drugs, serotonin-noradrenaline reuptake
inhibitors (SNRIs) work to selectively block reuptake of both noradrenaline and
serotonin, thereby increasing levels of both monoamines. The SNRIs have very little
affinity for other postsynaptic receptor sites and are therefore less likely to produce
some of the side effects associated with TCAs.
The Electrolyte Membrane Hypothesis
This hypothesis largely died out after the 1960s but may be reemerging with
the resurgence in the literature in the biochemistry and biophysics of membrane
functions. For example, the lithium-sodium counter flow mechanism in red cells has
been described and protein structural differences between patients with bipolar-polar
disorder and controls have been revealed. The mechanism of action of lithium in
bipolar disorder is still not understood.
The Neuroendocrine Hypothesis
According to this hypothesis, pathological mood states are explained or
contributed to by altered endocrine function. This theory historically grew out of
observations that altered mood states were associated with thyroid or Cushings
disease. Current explorations of pathophysiology using neuroendocrine theories have
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tended to result in research tools such as the dexamethasone suppression test
becoming diagnostic tools, perhaps prematurely.
Most of the serotonergic, noradrenergic and dopaminergic neurons are located
in midbrain and brainstem nuclei and project to large areas of the entire brain. This
anatomy suggests that monoaminergic systems are involved in the regulation of a
broad range of brain functions, including mood, attention, reward processing, sleep,
appetite, and cognition. Almost every compound that inhibits monoamine reuptake,
leading to an increased concentration of monoamines in the synaptic cleft, has been
proven to be a clinically effective antidepressant. Inhibiting the enzyme monoamine
oxidase, which induces an increased availability of monoamines in presynaptic
neurons, also has antidepressant effects. These observations led to the
pharmacologically most relevant theory of depression, referred to as the monoamine-
deficiency hypothesis.
The monoamine-deficiency theory posits that the underlying
pathophysiological basis of depression is a depletion of the neurotransmitters
serotonin, norepinephrine or dopamine in the central nervous system. Serotonin is the
most extensively studied neurotransmitter in depression. The most direct evidence for
an abnormally reduced function of central serotonergic system comes from studies
using tryptophan depletion, which reduces central serotonin synthesis. Such a
reduction leads to the development of depressive symptoms in subjects at increased
risk of depression (Neumeister et al., 2002; 2004a), possibly mediated by increased
brain metabolism in the ventromedial prefrontal cortex and subcortical brain regions.
Experimentally reduced central serotonin has been associated with mood congruent
memory bias, altered reward-related behaviors, and disruption of inhibitory affective
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processing (Hasler et al., 2004), all of which add to the clinical plausibility of the
serotonin deficiency hypothesis.
There is also evidence for abnormalities of serotonin receptors in depression,
with the most solid evidence pointing to the serotonin- 1A receptor, which regulates
serotonin function. Decreased availability of this receptor has been found in multiple
brain areas of patients with Major Depressive Disorder (MDD) (Drevets et al., 1999),
although this abnormality is not highly specific for MDD and has been found in
patients with panic disorder (Neumeister et al., 2004b) and temporal lobe epilepsy
(Hasler et al., 2007), possibly contributing to the considerable comorbidity among
these conditions. However, there is no explanation for the mechanism of serotonin
loss in depressed patients, and studies of serotonin metabolites in plasma, urine and
cerebrospinal fluid, as well as post-mortem research on the serotonergic system in
depression, have yielded inconsistent results. There is preliminary evidence that an
increased availability of the brain monoamine oxidase, which metabolizes serotonin,
cause serotonin deficiency (Meyer et al., 2006). In addition, loss of functional
mutations in the gene coding for the brain-specific enzyme tryptophan hydroxylase-2
explain the loss of serotonin production as a rare risk factor for depression (Zhang et
al., 2005).
Dysfunction of the central noradrenergic system has been hypothesized to play
a role in the pathophysiology of MDD, based upon evidence of decreased
norepinephrine metabolism, increased activity of tyrosine hydroxylase, and decreased
density of norepinephrine transporter in the locus coeruleus in depressed patients. In
addition, decreased neuronal counts in the locus coeruleus, increased alpha-2
adrenergic receptor density, and decreased alpha-1 adrenergic receptor density have
been found in the brains of depressed suicide victims post-mortem (Pandey and
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Dwivedi, 2007). Since there is no method to selectively deplete central
norepinephrine and no imaging tool to study the central norepinephrine system, solid
evidence for abnormalities of this system in depression is lacking.
While the classical theories of the neurobiology of depression mainly focused
on serotonin and norepinephrine, there is increasing interest in the role of dopamine
(Nutt, 2006). Dopamine reuptake inhibitors (e.g., nomifensine) and dopamine receptor
agonists (e.g., pramipexole) had antidepressant effects in placebo- controlled studies
of MDD (Goldberg et al., 2004). In the cerebrospinal fluid and jugular vein plasma,
levels of dopamine metabolites were consistently reduced in depression, suggesting
decreased dopamine turnover (Lambert et al., 2000). Striatal dopamine transporter
binding and dopamine uptake were increased in MDD, consistent with a reduction in
dopamine neurotransmission (Meyer et al., 2001). Degeneration of dopamine
projections to the striatum in Parkinson’s disease was associated with a major
depressive syndrome in about one half of cases, which usually preceded the
appearance of motor signs (Santamaria et al., 1986).
Experimentally reduced dopaminergic transmission into the accumbens has
been associated with anhedonic symptoms and performance deficits on a reward
processing task in subjects at increased risk of depression (Hasler et al., 2008; Hasler
et al., 2009). These findings are consistent with the clinical observation that depressed
patients have a blunted reaction to positive reinforcers and an abnormal response to
negative feedback (Murphy et al., 2003). Almost all established antidepressants target
the monoamine systems (Mann, 2005). However, full and partial resistance to these
drugs and their delayed onset of action suggest that dysfunctions of monoaminergic
neurotransmitter systems found in MDD represent the downstream effects of other,
more primary abnormalities. Despite this limitation, the monoamine deficiency
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hypothesis has proved to be the most clinically relevant neurobiological theory of
depression. New findings on the role of dopamine in depression emphasize the
scientific potential of this theory, and promising reports of antidepressant effects of
drugs that modulate the dopaminergic system (e.g., pramipexole, modafinil) in
difficult-to-treat depression underline its clinical relevance (Fava et al., 2005). The
development of neuroimaging techniques has opened up the potential to investigate
structural and functional abnormalities in living depressed patients.
FACTORS INFLUENCING DEPRESSION
Biogenetic risk factors
Twin, adoption and family studies are the genetic factors influenced the
genetic vulnerability factors of depressive disorder (Hamet and Tremblay, 2005).
Genetic variation causes biological dysregulation associated with depression. It was
observed that the functional polymorphism in the promoter region of the serotonin
transporter gene moderates the influence of stressful life events on depression (Capsi
et al., 2003). Its temperamental characteristics are harm avoidance and reward
dependence associated with specific biological function increase the vulnerability to
depression (Cloninger et al., 1993; Heath et al., 1994).
Psychological factors
Cognitive phenomena such as schemas and automatic thoughts mediate
depression emotion and behavior (Golagman et al., 1998; Young et al., 2003).
Stressful events can activate these dysfunctional schemas, facilitate cognitive
distortions and result in automatic thoughts which reflect the negative triad about
the self, world and future (Beck et al., 1979).
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Apart from genetic aspects, intergenerational factors also increase the
vulnerability to depression. Impaired social skills, excessive interpersonal
dependency and excess interpersonal inhibition are three other non-exclusive
domains of vulnerability to depression (Joiner et al., 2002).
Somatic risk factors
Physical illness such as pain, thyroid disease, immunity problem, cancer,
viral infections, cardio vascular system (CVS) and skin disorders increase the
vulnerability to depression. Drug abuse, intoxication with or withdrawal from
substances such as alcohol, amphetamine and sedatives increased the vulnerability to
depression.
Social –cultural risk factors
Socio-cultural activities such as nuclear family, extra familial structures or
traditional social cultures break down leads to less intergenerational continuity and
which causes less importance to family values results in depression. American
paradox, economic expansion and increased social recession such as high number of
divorcee, suicide, violence leads to depression (Myer, 2000).
Environmental factors
Depression has both genetic and environmental factors. Chronic mild stress
(CMS) is a key factor in the environmental component of depression. Exposure to
CMS causes depression. Chronic mild stress causes atropy of CA3 pyramidal
neurons of hippocampus include a decrease in the number and length of apical
dendrites (Duman et al., 1997) and decrease proliferation of cells in the dentate gyrus
of the hippocampus along with the alteration in processes and number of neurons
(Gould et al., 2002). CMS altered AMPA–receptor glu-R1 sub unit level in
hippocampi and nucleus accumbens exerts different neurobiochemical and
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behaviuoral resilence. Volumetric and cellular loss occurs in the subgeunal frontal
cortex in depressive patients as a result of down regulation of brain derived
neurotropic factor (BDNF) levels in hippocampus attributing to atropy of neurons
and reduced neurogensis in the hippocampus and subgenual frontal cortex. BDNF and
Glu- system plays a role in the neuronal plasticity which may be involved in the
pathophysiology and treatment of mood disorder (Zangen and Shavlev, 2003).
TREATMENT
Antidepressants hold the third rank among the most prescribed of therapeutic
agents’ world wide. There are about two dozen antidepressants agents which
function by nine different pharmacological distinct functions (Stahl, 1998).
Antidepressants act indirectly by enhancing 5HT tone or 5HT receptors through the
inhibition of reuptake and presynaptic 5HT1A autoreceptors are a primary target of
several antidepressants which enhance the extracellular 5HT or act directly (Haddad
et al., 1998; Blier and Ward, 2003).
The conventional antidepressants act by producing effective changes in the
corticosteroid receptors of HPA axis followed by clinical recovery (Holsber, 2000)
and prevents atropy either by blocking or opposing the stress induced death (Manji et
al, 2000; Gould et al., 2002).
Mechanism of action of Antidepressants
Neurotransmitter action is terminated by the uptake by transporters which are
present both on neurons and astrocytes (Fullers and Wong, 1990; Bal et al., 1997;
Inaz et al., 2001). Elevation of norepherine (NE) levels by the blockade of uptake has
a profound effect on astrocytic neuro- transmitter receptor expression and cellular
signalization cascade modulation. Astrocytes express beta1 and beta 2
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adrenorecptors in the brain (Hostli and Hosli,1993) responds to antidepressants by
decreasing the density of receptors (Sapena et al., 1996). The following are the
possible mechanism of action
TCAs prevent presynaptic reuptake of the amines (NA and 5HT)
MAOI reduce the activity of MAO in breaking down presynptic amines
(leaving more available for release into the presynaptic cleft.
Some may block post synaptic receptors directly (Brown and Bennet, 2003).
Mainly inhibits the reuptake of biogenic amines 5HT, norepinephrine and
dopamine into presynaptic nerve terminals.
Enhances uptake of monoamines on the synapses and reversed the stress
induced changes in hippocampal formation and modulate glutamate receptor
function.
TCAs regulate tyrosine hydroxylase activity in dopaminergic brain regions
including cell body and terminal field of mesolimbic and migrostraital
pathways of the rat brain (Rosine et al., 1995).
SSRIs acts by inhibiting serotonin transport and it increases serotonin in
somatodendritic area of serotonergic neurons.
Monoamine oxidase inhibitors shows immediate action but its clinical
response requires weeks or months.
Down regulation of monoamines occurs directly from postsynaptic action
and betadrenergic 5HT receptors at postsynaptic level and shows proximal
effects on G-receptor coupled to G protein and distal effects of G protein to
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effector enzymes with added effect on adenylacyalse and phospsholipase
(Avissar and Scheriber, 2006).
The initial delay in clinical action results from neurobiological adaptive
mechanism secondary to the activation of primary target which encompasses changes
in presynaptic activity of monoamine containing neurons and Postsynaptic effect
in corticolimbic area.
CHRONIC ADMINISTRATION OF ANTIDEPRESSANTS
Enhances uptake of monoamines on the synapses and is supposed to reverse
the stress induced changes in the hippocampus formation and modulate glutamate
receptor function (Mc-Even et al., 2002).
Significantly increases the glial derived neurotropic factor (GDNF) release
from C6 glioma cells which is further potentiated by HT (Hisoka et al., 2001).
Norepineprine stimulates C6 glioma and cortical astrocytic cells to produce
glial derived neurotropic factor via beta adrenergic receptor stimulation and
adenylcylase activation (Arisan et al., 1989). Decreased monoamine receptor
densities in cell culture system such as C6 glioma cell lacking presynaptic
cleft.
Activation of beta adrenoreceptors induces the synthesis of nerve growth
factor, fibroblast growh factor (FGF), transforming growth factor (B1, B2) hence
provide neuroprotection against glutamate induced and ischemic neuronal damage
(Junker et al., 2002).
Prolonged administration causes desensitization of some 5HT1A receptors,
which in turn no longer inhibit neuronal impulse flow hence, turned on
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(Richelson, 1982). This reaction causes increased release of 5HT from axon
terminals leading to desensitization of postsynaptic 5-HT receptors at final
step. This desensitization result in therapeutic action of SSRIs. The desired
pharmacological profile of SSRI is to produce powerful and delayed
disinhibition of 5HT neurotransmission in the pathway from mid brain raphe
to prefrontal cortex is presumed to mediate the antidepressant effect of SSRI
(Baxter et al., 1989; Foote and Morrison, 1987; Blier and De-
Monotny.,1994).
All monoamines increase BDNF astrocyte synthesis, secretion suggests the
existence of positive reciprocal interaction between monoaminergic neuronal
activity and astrocyte cross talk which has a dynamic role in mediating
neuronal plasticity and tropic functions in the brain (Mojcajurie et al., 2006).
Up regulation of BDNF into mid brain denotes antidepressant effect. BDNF
is known to influence the survival and function of mature neurons and
characterized by their action during development and maturation of neurons.
Down regulation of post synaptic beta adrenergic receptors, 5HT1 and 5HT2
receptors at post synaptic level, in response to chronic administration.
ANIMAL MODELS OF DEPRESSION
Earlier studies revealed that structural alterations occur in response to stress in
rats, but are reversible upon administration of antidepressants (Manji et al., 2000).
Swimming is one of the most common analytical technique used to surrender or
resistance to fatigue or depression (Zhang et al., 2002, Nestler et al., 2002b).
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Different animal models of depression are:
Learned helplessness (LH)
The LH paradigm uses a stress-exposure period in which rats or mice are
exposed to inescapable stress (e.g., electrical foot shock) in one or more sessions. In a
subsequent session, the animals are tested for their performance in an active
avoidance test. In a typical active avoidance test, animals are confined to one side of a
shuttle box chamber where foot shocks are delivered but the animal has the
opportunity of actively escaping the foot shock. Animals previously exposed to
inescapable stress show reduced abilities to escape in this model. The reduced ability
to escape is restored by different forms of antidepressant treatment, including tricyclic
antidepressants, selective serotonin reuptake inhibitors, monoamine oxidase
inhibitors, and electroconvulsive shock therapy (Martin et al., 1990; Sherman et al.,
1982). This model has good validity for predicting antidepressant efficacy (Willner,
1984).
Forced swim test (FST)
The FST involves placing a rat or mouse in a cylinder with enough water so
that it cannot touch the bottom with its hind paws (Porsolt et al., 1977a,b, 1978). A
normal animal will show an immediate burst of activity, try to escape, and then
eventually adopt an ‘‘immobile’’ posture, where it will make only those movements
necessary to keep its head above water. The development of immobility may be
facilitated by prior exposure to the test and a 24-h prior preexposure to the test is often
used (Porsolt et al., 1978). Immobility is quantified during brief test periods and
classical antidepressants such as the monoamine oxidase inhibitors, tricyclics, and
atypical antidepressants all decrease the duration of immobility in rats and mice in a
dose-dependent manner (Borsini and Meli, 1988; Porsolt et al., 1977a,b).
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Tail suspension test (TST)
The TST is conceptually similar to the FST and is suggested to have greater
sensitivity. A mouse is suspended by the tail in this test and observed for the extent of
immobility versus active movement (Steru et al., 1985). Similar to the FST, the TST
is also based on the adoption of a passive response in a stress situation. Acute
antidepressant treatment given prior to the test reduces immobility time in the TST
and it is considered to have good predictive validity (Cryan et al., 2005; Perrault et al.,
1992; Steru et al., 1985).
Hyponeophagia paradigms
Examples of hyponeophagia tests that are used in rats and mice are novelty
induced hypophagia (NIH) and novelty suppressed feeding (NSF) paradigms. They
are anxiety based and compare feeding behavior in an anxiogenic versus a
nonanxiogenic environment. The stress employed in these models is very mild
relative to most other tests for antidepressant action, and consists of placing the
experimental animal in a novel environment to induce anxiety during testing. The
animal experiences conflict between the desire to approach and feed or drink, and the
anxiety-induced avoidance of the novel environment (Dulawa et al., 2004).
Chronic unpredictable mild stress
In comparison to LH and FST/TST procedures that rely on relatively short
term aversive stress exposure, the chronic unpredictable mild stress (CUS) paradigm
was developed to study neural changes that result from stress of a more chronic
nature. CUS paradigms aim to model a chronic depressive like state that develops
gradually over time in response to stress, and is thus considered more naturalistic in
the induction. Rats or mice are exposed to a series of different stress conditions over a
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period of several weeks. Several stressors (6–8) are applied (1 or 2 per day) for
several hours each day. Typical stressors include overnight illumination, periods of
food or water restriction, cage tilt, and isolation or crowded housing. The sequential
and unpredictable stress exposure decreases the likelihood of the animals habituating
to any one reoccurring condition (Aguilera, 1998; Magarin˜os and McEwen, 1995;
Tannenbaum et al., 2002).
Hedonic sensitivity
Methods for quantifying hedonic sensitivity include conditioned place
preference procedures in which animals learn to associate a particular environment
with reward experience, brain stimulation reward (BSR) paradigms, and quantifying
consumption of sweet solutions. Quantifying consumption of sweetened fluids
(sucrose or saccharin) is the most commonly employed endpoint for assessing CUS
effectiveness. Rats previously habituated to sucrose are typically given a choice of
drinking sucrose versus water in a two-bottle test. While control rats typically show a
preference for drinking weak sucrose solutions, rats exposed to CUS loose this
preference. The development of this effect can be demonstrated by repeated sucrose
preference testing during the course of CUS exposure. The time-dependent reversal of
this effect with chronic antidepressant treatment can also be demonstrated by repeated
testing.
Early life stress (ELS)
Early life adverse experience is an important predisposing factor for
psychopathology in humans. Several human studies indicate that exposure to stress or
adversity early in life increases the risk for depression, and that stress exposure may
interact with genetic risk factors (Agid et al., 1999, 2000; Caspi et al., 2003; Kaufman
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et al., 2006; Weiss et al., 1999). The ELS models typically employ stress exposure
during critical periods of development and result in stable phenotypic changes. ELS-
induced changes that have been particularly replicable involve alterations in neural
systems that regulate or respond to stress such as the hypothalamus pituitary axis and
include endocrine, neurochemical, and behavioral alterations.
Social defeat
Social stress represents a significant type of adversity in many species and is
thought to play a role in the development of depression and other psychopathology in
humans (Agid et al., 2000; Bjorkqvist, 2001; Huhman, 2006).
The use of social conflict as a stressor and the use of social interaction as a
quantifiable endpoint both have validity for depression (Heim and Nemeroff, 2001).
Experimental models in rodents frequently utilize a conflict situation that results in
one animal becoming or retaining dominant status and another ending up subordinate
or ‘‘defeated’’. A phenotypic trait produced in these models is social avoidance,
which can be quantified and is suggested to model social withdrawal in human
depression (Berton et al., 2006; Koolhaas et al., 1997; Van-Kampen et al., 2002).
LIMITATIONS
Depressive patients are unwilling to take medication as the depression affects
both physical and mental conditions. Less than 20% of the affected receive
medication, and less than 10% take suitable medication, though the inhibitory action
of antidepressants on reuptake of monoamine are immediate, but their clinical
response requires weeks of treatment (Lepine et al., 1997; Parikah et al., 1999;
Hyman, 1999). Among the antidepressants SSRIs constitutes 80% of antidepressants,
response rate of SSRIs is about 60 % at 6 weeks whereas clinical response is
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estimated as 50 % decrease in initial severity. Other antidepressants such as SNRI or
TCAs inhibit the reuptake of noradrenaline, the presence of side effects limits its
use. The effects of clinical therapies are not desirable. Cessation of medication is
common in clinical treatment (Anderson and Tomenson,1995; Pampallona et al.,
2002). Patients are unwilling to continue medication due to severe side effects
leading to poor compliance and poor therapeutic effect (Demyttenare, 2003).
ADVERSE EFFECTS OF CONVENTIONAL ANTIDEPRESSANTS
Tricyclic antidepressants
TCAs inhibit sodium channels at high dose leads to cardiac arrhythmia,
seizures, anxiety, sleep disturbances, sexual dysfunction and gastro intestinal
disturbances (Richelson, 1982).
Selective serotonin reuptake inhibitors
SSRIs cause anxiety, akathisia, insomnia and sexual dysfunction, decreases
appetite, nausea, weight loss (Stahl, 1998; Balon, 1997; Stein and Hollander, 1994).
Noradrenaline specific reuptake inhibitors
NRIs cause dryness of mouth, constipation, sexual dysfunction (DeBattista
and Shatzberg, 2000).
Monoamine oxidase inhibitors
MAOIs produce weight gain, CNS stimulation, liver damage and convulsions.
Lithium salts causes diarrhoea, thyroid enlargement, hypothyroidism, tremor and
renal effects.
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Noradrenaline and dopamine reuptake inhibitors
Noradrenaline and dopamine causes psychomotor retardation, anhedonia
hypersomnia, cognitive slowing, craving inattention, pseudodementia (Breese et al.,
1974).
TRADITIONAL MEDICINE
World Health Organization (WHO) offers the collective term Traditional
medicine (TM) to refer systems of medicine such as traditional Chinese, Indian
Ayurveda, Arabic Unani and various systems of indigenous medicine. TM is also
referred as Complementary or Alternative or Non Conventional Medicine (WHO,
2002).
ADVANTAGES OF TRADITIONAL MEDICINE (TM)
Easy availability, accessibility, affordability though quality and mechanism
differ in various parts of the World.
Many of the developing countries are on the increased consumption due to
limited availability and accessibility of Modern medicine which is expensive
and often unaffordable.
Available at the local level and easily affordable (Zhang, 2004).
Adds the advantage that it has no drug interventions.
It has right quality of material and apt processes are used from sourcing to
marketing.
No contamination, adulteration or spiking (Kaened, 1999).
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Emerging diseases where no medicines are available have provoked the
interest in medicinal plants as a significant source of new medicine (Dhaunkar
et al., 2000).
Cost effective and has limited systematic studies to compare.
Contain several chemicals substances, its medicinal action are due to the
co-operation of the constituents.
Possess natural affinity to the body system, non specific, normalizing action
shows minimal disturbances in cellular environment, minimal psychological
changes.
Recent studies supported the general belief of TM as affordable over modern
medicine (Ernest, 2000; Evans, 1997).
Systematic Pharmacognostical, detailed Phytochemical investigations and
innovative Pharmacological studies provide scientific information on the quality,
efficacy, safety or toxicity of traditional drugs of plant origin which will enhance the
standardization and acceptance of Traditional medicine globally.
Table 1 List of medicinal plants reported to possess antidepressant effect
Biological name Parts used Family Citation
Argyreia nervosa Root, leaf Convolvulaceae Chopra et al., 1956
Baccopea moniera Whole plant Scrophulariceae Aithal and Sirsi, 1961
Banux Houpei Whole plant Chinese formulation Luol et al., 2000
Wang et al., 2005
Casimiroa edulis leaf Rutaceae Mora et al., 2005
Celastrus paniculatus Seeds and oil Celestraceae Nalini et al., 1995
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Centella asiatica Whole plant Umbelliferae Ganachari et al., 2004
Cimifuga racemosa leaf Ranunculaceae Borrelli and Ernst, 2003
Winterhoff, 2000
Clitoria ternata Whole plant Leguminosae Norte et al., 2005,
Cosentino and Mc-Norte,
2004
Crocus sativus stigma Iridae Akhonda et al., 2005
Croton zehnterni leaves Euphoriabaceae Guorgi et al., 1991
Elaeocarpus senticosus Seed fruit Tiliaceae Singh et al., 2000
Gastrodia elata leaves Orchidceae Zhou et al., 2006
Glycyrrhiza glabra Root,
rhizomes
Leguminosae Dinesh and Sharma, 2005.
Ginkgo biloba Root Gingobeacea Sakakaribari et al., 2006
Hibiscus subdariffa Leaves Malvaceae Amos et al., 2003
Hypercium perforatum Aerial parts Hypericeae Sanchez et al., 2002
Butterweck et al.,1984
Panax ginseng Root Arilaceae Atlele et al., 1999
Rudakawich et al., 2001
Passiflora foetida/alata leaves Passilforacea Flavino, 2001
Polygala tenurifolia Root Polygalaceae Ikaya and Tunkava, 2004
Salvia elegans Leaves Labitae Maribel et al., 2006
Securdaca
longepedunculata
Leaves Polygalaceae Adebiye et al., 2006
Withania somniferum Root Solaneceae Bhattacharya et al., 2009
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ARGYREIA NERVOSA (AN)
VERNACULAR NAMES
English Elephant creeper
Telugu Samudrapalai
Tamil Samudrapaccha
CLASSIFICATION
Kingdom Plantae
Subkingdom Tracheobionta (Vascular plants)
Superdivision Spermatophyta (Seed plants)
Division Magnoliophyta (Flowering plants)
Class Magnoliopsida (Dicotyledons)
Subclass Asteridae
Order Solanales
Family Convolvulaceae
Genus Argyreia
Species nervosa
Botanical Source Argyreia nervosa
Leaves
Family Convolvulaceae
Synonym Argyreia speciosa
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Habitat
The plant grows on river banks, edges of lakes and as an under-growth in
semi deciduous forests climbs over bushes to elevation of 1000 m found throughout
India and often cultivated in Western regions (Nadkarni, 1994a).
Botanical description of the plant
AN is soft woolly climber with hardy woody stalk bearing soft silky heart
shaped leaves of 9-12 cm long and 8-10 cm breadth. Leaves are larger with acute
apex and cordate base. Flowers are purple, silky pubescent and wooly inside with
bract. Corolla is rosy and wooly. Calyx is white, tomentose outside with
glabrous ovary inside. Fruits are globose and indehiscent berry (Nadkarni, 1994a;
Varier, 1997a).
Ethnoclaims
In India, the leaves are used to prevent conception by the tribals of Rajasthan,
whereas in Assam and Bihar leaves are used as vegetable (Wealth of India). Roots
are used as an appetizer, anti-inflammatory, aphrodisiac, expectorant, cardiotonic
and brain-tonic. Roots are used to treat obesity, diabetes, anemia, ulcers, wounds,
synovitis and gonohorrea (Varier, 1997a). Leaves are used to treat boils, swellings,
ring worm infestations, externally to treat itches, eczema, wounds and skin diseases
(Asima and Satyesh, 2003a). In Hindu medicine, the root is used as alternative tonic
and used for rheumatic affections and diseases of the nervous system (Nadkarni,
1994a).
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Phytochemical Review
Seeds
Miller, (1970) isolated and identified lysergic acid (LSD), isolysergic acid and
ergoline alkaloids from the seeds of Argyreia nervosa. They were identified by thin
layer chromatography, melting point, ultraviolet and infrared spectroscopical
methods.
Chaos and Mardersian, (1973) reported the presence of nineteen indole
alkaloids in the seeds of Argyreia and were identified by thin layer chromatography
and paper chromatography.
In particular lysergene, festuculine, setoclavine, iso-clavine, agroclavine,
elmyoclavine, ergine and isoergine were isolated by column chromatography and
was characterized by thin layer chromatography and infra red analysis. Penniclavine,
chanoclavine - I and II, ergometrine, ergometrinine, lysergic acid (LSD), alpha
hydroxyl ethylamide, isolysergol, racemic chanoclavine–II, molliclavine, lysergol and
iso-lysergic acid, α-hydroxyl iso-lysergic acid were identified by thin layer
chromatography. Ergine and isoergine were found in high concentration. Lysergine,
setuclavine, iso-setoclavine, chanoclavine–II, iso-setoclavine, iso-lysergol and
molloclavine were identified for the first time in the species.
Agarwal and Rastogi, (1974) identified the presence of ergometrine, other
related constituents such as caffeic acid and ethyl caffeate in AN.
Mann et al., (1999) reported the presence of N-formylloline alkaloids and
flavanoidal sulphates from the roots of AN. Shukla et al., (1999) isolated hydroxy-
cinnmate and scopeltin from the roots of AN.
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Rahman et al., (2003) isolated argyroside from the seeds of AN, a steroidal
glycoside chemically named as 24 R ergost-5-en-11-oxe-3beta–ol–alpha D-
glucopyranoside whose structure was elucidated by spectroscopic analysis and
chemical methods.
Pharmacological Review
Antimicrobial activity
Mishra and Chaturvedi, (1978) reported the antibacterial and antifungal effect
for the oil isolated from the seed of AN.
Antifungal and phytotoxic activity
Shukla et al., (1999) isolated hydroxycinnamate and scopeltin from AN and
were screened against fungi. AN showed significant antifungal effect against
Fusarium fusiformis, Fusarium semitectum and Alternaria alternate and exhibited
complete inhibition of root growth in germinated wheat.
Anti- inflammatory activity
Gokhlae et al., (2002) administered ethanolic extracts of AN at the dose of 50,
100, 200 mg/kg orally and studied anti-inflammatory activity in acute and chronic rat
inflammatory models. AN showed significant anti-inflammation effect by reduction
in paw edema and prevented the accumulation of inflammatory cells.
Immunomodulatory effect
Gokhale et al., (2003) administered aqueous extract of AN at the dose of 50,
100, 200 mg/kg to sheep red blood cells and oxazolone induced hypersensitive mice.
AN showed significant immunomodulatory effect by increased production of
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Institute of Pharmaceutical Technology, SPMVV, Tirupati 45
antibodies and white blood corpuscles (WBC) cells in mice and restored the
myleosuppressive effects induced by cyclophosphamide.
Antidiarrhoeal activity
Hydroalcoholic extract of flowers of AN was administered at the dose of
50, 100 and 150 mg/kg orally and showed significant antidiarrhoeal effect by
inhibition of intestinal propulsion and reduction in faecal matters (Rao et al., 2004).
Aphrodisiac property
Subramoniam et al., (2007) reported enhancement of mating and mounting
behaviour in mice with aqueous extract of roots, leaves and flowers of AN.
Nootropic effect
Joshi et al., (2007) reported nootropic activity of aqueous extract of roots of AN
in scopolamine and diazepam induced memory impairment in passive avoidance
paradigm and elevated plus maze and was attributed to inhibition of acetylcholine
esterase activity.
Analgesic and anti-inflammatory
Alcoholic and aqueous extract of AN of root was administered at the dose of
30, 100, 300 mg/kg to inflammatory models of mice. AN showed significant
analgesic effect by increased basal reaction time in hot plate, inhibited the writhing
induced by acetic acid and reduced the paw edema (Bacchav et al., 2009).
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Effect on central nervous system
Hydroalcoholic extract of AN was administered at the dose of 100, 200 and 500
mg/kg to rats was subjected to neuropharmacolgical screening. AN showed
significant dose dependent reduction in spontaneous motor activity and potentiated
pentobarbital sodium induced sleep (Galani and Patel, 2009).
Anticonvulsant activity
Vyawahare and Bodhankar, (2009) studied the effect of hydroalcoholic extract
of various doses of AN root were administered to pentylene tetrazole and maximal
electrical shock induced convulsions in rats. AN showed significant anticonvulsant
effect against pentylene tetrazole and maximal electrical shock induced convulsions
Anti obesity effect
Shivkumar et al., (2011) reported that ethanolic extract of roots of AN was
administered to rats. AN showed significant antiobesity effect by decreased weight
of liver and adipose tissue.
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JASMINUM SAMBAC (JS)
VERNACULAR NAMES
English Jasmine
Telugu Mallgae
Tamil Malli
CLASSIFICATION
Kingdom Plantae ( Plants )
Subkingdom Tracheobionta (Vascular plants)
Superdivision Spermatophyta (Seed plants)
Division Magnoliophyta (Flowering plants)
Class Magnoliopsida - Dicotyledons
Subclass Asteridae
Order Scruphulariales
Family Oleaceae.
Genus Jasminum.
Species sambac
Botanical Source Jasminum sambac
Leaves
Family Oleaceae
Synonym Arabian Jasmine
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Habitat
It is grown as an ornamental shrub in gardens and cultivated throughout the
tropical and subtropical parts of India (Dastur, 1952a).
Botanical description of the plant
JS is a sub erect shrub with young shoots of ovate or elliptic glabrous simple
leaves, entire margin, acute apex and opposite arrangement. Flowers are white,
solitary, and fragrant with lobed calyx. Fruits are globose, berries and blue black
when ripen (Asima and Satyesh, 2003b; Varier, 1997b).
Ethnocliams
In China flowers of JS are used to flavour the tea. Leaves, roots and flowers
are used as lactifuge. The whole plant is used as diuretic, emmengogue,
antihelminthtic and deobstruent. Otto from flowers is used as deodorant and
balsam from leaf preparations are used to treat insanity (Nadkarni, 1994b).
Phytochemistry Review
Root
Zheng et al., (2004) reported the presence of dotricontanol, oleanolic acid,
daucosterol and hesperidin and dotriacontanic acid from the roots of JS by spectral
and physical methods.
Flowers
Inagaki et al., (1995) reported the presence of glycosidic precursors such as
benzyl 6-O- ß-D-xylo pyranosyl ß-glucopyranoside (beta –primeveroside), 2- phenyl
ethyl ß primeveoroside, 2- Phenyl ethyl 6-O – alpha L–rhamnoside.
Ana et al., (2008) reported the presence of alkaloids, glycosides and tannins
from the stem and leaves of JS.
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Pharmacological Review
Anti-lactation activity
Shrivastav et al., (1988) reported that paste of flowers of JS applied to breast
suppressed puerperal lactation. JS flowers showed significant antilactation effect by
reduction in serum prolactin.
Antiviral effect
Chiang at al., (2003) reported that flowers of JS at the concentration of 100-150
microgram/ml exhibited significant antiviral effect against simplex and adenovirsus.
Antibacterial activity
Ana et al., (2008) reported significant antibacterial effect of JS against
Staphylococcus aureus and Escheri coli by disc diffusion method. Priya and Patria.,
(2008) reported significant antibacterial activity of JS against the Staphylococcus
aureus, Salmonella typhi and Proteus mirabilis.
Antiproliferative activity
Wamidh and Mahanesh, (2010) reported significant anti-proliferative activity
of flower extracts of JS against HEP-2 (breast epithelial adenocarcinoma), MCF-
7(larynx carcinoma) and Vero African green monkey kidney cell lines.
Antimicrobial and antiacni activity
Tsung et al., (2010) reported antimicrobial and antiacne effect of JS against
Propionibacterium acnes evaluated by the production of cytokines in human
monocyte cells.
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Anti inflammatory
Methanolic extract of JS showed the inhibitory effects on the
proinflammatory mediator secretion in coculture of THP-1 cells with heat killed
Propionibacterium acne (Tsung et al., 2010).
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PASSIFLORA FOETIDA (PF)
VERANACULAR NAMES
English name Passionflower, Stinking Passion.
Telugu Tellajumuki.
Tamil Siruppunnaikali.
CLASSIFICATION
Kingdom Plantae
Division Magnoliophyta
Class Magnolipsida
Order Malpighiales
Family Passifloraceae.
Genus Passiflora
Species foetida.
Part used Passiflora foetida
leaves
Family Passifloraceae.
Synonyms Passion flower
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Habitat
It is common plant grown in South India found at an elevation of 500 m,
throughout moist and damp places (Nadkarni, 1994c).
Botanical description of the plant
PF is a perennial tendril climber with hispid, thin wiry woody stem, covered
with sticky yellow hairs. Leaves are 5-10 cm long, equally wide, trilobed, viscid,
hairy, acute apex, sub cordate base; hispid-hirsute on both sides holding a petiole 2-5
cm. Flowers are solitary in axils, 4-5 cm wide, purple and white with 3-7.5 cm long
pedicled. Fruits are sub-globose, yellowish orange to red when ripe, thin leathery
skinned 2 -3cm thick with numerous seeds (Nadkarni, 1994c).
Ethnoclaims
PF is used by Gond tribes for cancer (Tiwari and Padhye, 1993), decoction
of the leaves are used for giddiness and headache (Karnick, 1994), asthma (Nadkarni,
1994c; Vedavathi et al., 1997b), in Suriname traditional practice it is used to treat
nervous disorders and as expectorant in Brazil. PF is also used as sedative and
antihypertensive (Capasso and Sorrentino, 2005).
Phytochemical Review
Leaves and stem
Kapoor et al., (1972) reported the presence of alkaloids and flavanoids from
the stems and leaves of PF. Lutomski and Malek, (1975) reported the presence of
harmaline alkaloids in PF. Mabry et al., (1982) reported the presence of C-
glycosides from the leaves of PF. Echverri et al., (2001) reported three polypeptides,
alpha pyrones and passiflorines from the hydroalcoholic extract of aerial parts of PF.
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Seeds
Siriamorupur and Yang, (2005) measured the total lipids by gravimetric
method and its fatty acid composition was analyzed by gas liquid chromatography
(GLC). The percentage of lipid content was found to be 19-47%.
Leaves
Pongapan et al., (2007) reported the amount of vitexin (0.04 to 0.13% w/w) by
reverse phase (RP-HPLC) High performance liquid chromatography technique using
an isocratic elution with mobile phase composing of isopropanol: tetrahydrofuran :
water (5:15:80v/v) and 0.3 % formic acid. Bendini et al., (2007) reported the phenolic
content of PF quantified by Spectrophotometric methods, HPLC and Mass
Spectrometry.
Pharmacological Review
Insect deterrent activity
Echverri et al., (1991) reported ten flavones and glycosides isolated from leaf
resin of PF. PF showed significant insect deterrent activity at the concentration of 40
ppm against Dione Juno larvae.
Lehishmanicidal and cytotoxic activity
Echverri et al., (2004) isolated the Passifloricin A from PF and showed
leishmanicidal effect at the concentration 200ppm against Leishmania panamensis
amastigotes. Echverri et al., (2004) isolated Passifloricin from leaf and showed
cytotoxicity by enzyamatic micromethod.
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Antiproliferative activity
Ethanolic extract of PF showed antiproliferative effect against SKBR3
human breast adrenocarcinoma cell lines using MTT assay (Pongapan et al., 2004)
Hypoglycemic activity
Alcoholic extract of leaves of PF was administered at the dose of 100 and 200
mg/kg body weight to alloxan- induced albino rats. PF showed significant reduction
in blood glucose in alloxan treated rats (Dhanabal et al., 2004).
Antibacterial activity
Mohanasundari et al., (2007) reported anti- bacterial effect of ethanol and
acetone extracts of leaf and fruits at the dose of 100, 200 300 and 400mg/mg against
the strain Pseudomonas putida, Vibrio cholerae, Shigella flexneri and Streptococcus
pyrogens
Antimelanogenesis activity
Ethanolic extract of fruit and stem of PF showed antimelanogenesis effect by
1,1 – diphenyl 2-picryl hydrazyl (DPPH) radical scavenging assay, tyrosinase
inhibition activity and melanin formation inhibition assay using B16 melanoma cells.
PF showed significant inhibition of melanin production in B16 melanoma cells
cytotoxicity (Arung et al., 2009).
Anti-oxidant activity
Methanolic extracts of PF showed antimicrobial activity against E. coli which
was tested by agar diffusion and turbidity assays. PF exhibited antioxidant effect
against E.coli (Bendini et al., 2007).
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SAPINDUS EMARGINATUS (SE)
VERNACULAR NAMES
English: Soapnut tree
Hindi: Ritha
Telugu: Kunkutikaya,
CLASSIFICATION
Kingdom: Plantae
Division: Phenerogamia
Class : Dicotyledon
Series : Disciflorae
Subclass: Polypetale
Order: Sapindales
Family : Sapindaceae
Genus : Sapindus
Species: trifoliatus /emarginatus
Habitat
SE is a medium sized to large, deciduous tree found in Andhra Pradesh and
Karnataka. It is native of south India, grown on the coast and in open forest at low
elevations and in the plains of North India. It is commonly found in evergreen
Part used Sapindus emarginatus
leaves
Family Sapindaceae.
Synonyms Sapindus laurifolio /
Sapindus trifolaitus
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forests of Konkan and Kanara along with Westren Ghats and South India (Varier,
1997c; Vedavathi et al., 1997b).
Botanical description of the plant
SE is a medium sized deciduous tree grown upto a height of 2 m, leaves
with pinnate arrangement. Flowers are white, polygamous; fruits are fleshy with
black seeds.
Ethno botanical claims
The fruit preparations are used to treat ear ache, snake bite, ante-partum and
post partum treatment so as to induce and restore the normal condition of uterus
after child birth. Roots are used as expectorant, demulcent, (Nadkarni, 1994d;
Vedavathi et al., 1997b) and used in hemicranias, hysteria and epilepsy (Varier,
1997c). Leaves are used to treat painful joints, gout and rheumatism (Dastur, 1952b).
SE is claimed to be used in hysteria and melancholia.
Phytochemistry Review
Seeds
Ucciani et al., (1994) reported the presence of cyanolipids from the seed oil of
SE. Gupta and Kharya, (1996) evaluated the phytochemical and pharmacolgical
studies of the seeds of SE.
Pericarp
Yamasaki et al., (2001) isolated and identified aceylated triterpene saponins
such as heragenin 3-o-2- o-acetyl Beta D- xylopyranosyl)- (1 3) alpha L-
rhamnopyranosyl -(1 2) arabinopyranoside, 23 O- acetyl-hederagenin 3- O (4-O-
acetyl-beta -D -xylopyranosyl-(1 3), alpha-L-rjhamnopyranosyl -(1 2), alpha -
Larabinopyranoside andoleanolic acid 3-o-(4- acetyl-beta -D-xylopyranosyl (1 3)-
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alpha rhamnosyl -(1 2) arabinopyranoside and from the pericarp of SE.
Rajesh et al., (2005) reported six saponins from the pericarp of SE and
structures were identified by spectral means.
Pharamacological Review
Antifertility effect
Boghankar et al., (1974) administered alcoholic extract of SE to pregnant
albino rats and showed significant antifertility effect.
Hypotensive effect
Alcoholic extract of SE at the dose 10-20 mg / kg was administered to male
cats and dogs and showed significant hypotensive effect (Singh et al., 1978).
Antihelmintic effect
Lal et al., (1978) reported significant antihelminthic effect of SE against
Ascardia galli worms in birds by in vitro methods.
Antispermatogenic and antiandrogenecity effect
Fruit extract of SE was administered at the dose of 10 mg/kg and showed
significant antispermatogenic effect due to testicular lesions and inhibition of
spermatogenesis at the primary spermatocyte stage in male gerbils (Dixit and Gupta,
1982).
Anti fouling effect
Sawant et al., (1992) reported significant suppression of macrofoulers in
estuarine water and bacterial fouler in lab with methanolic extracts of SE on
aluminum coupons.
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Antinoceptive activity
Arulmozhi et al., (2004a) administered aqueous extract of SE at the dose of
100 mg/kg to rats and showed significant antinociceptive effect against chemical,
thermal and nitroglycerin induced hyperalgesia.
Antimigraine activity
Arulmozhi et al., (2004b) administered aqueous extract of pericarp of SE to
migraine rabbit and guinea pig models and showed siginificant antimigraine effect
by 5-HT (2B) receptor inhibition and inhibition of serotonin release against induced
migraine models.
Anti-inflammatory activity
Arul et al., (2004) administered ethanolic extract of SE to inflammatory
models of rats. Inflammation was induced by carageenan and cotton pellet
granuloma. SE showed significant inhibition of paw edema, migration of leucocytes
and reduction on the granuloma weight induced by cotton pellet.
Arulmozhi et al., (2005d) administered lyophilized aqueous extract of SE at
the dose of 20 and 100 mg/kg intraperitoneally to acute inflammatory models of rats
and showed significant inhibitory effect against the inflammatory mediators such as
5 COX CTA2 and NOS.
Antihyperalgesia effect
Arulmozhi et al., (2005a) administered aqueous extract of SE at the dose 2,
20 and 100 mg/kg to migraine models of rats and showed significant antimigraine
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and antihyperalgesia effect by studing apomorphine induced climbing behaviour,
licking latency on hot plate and the abdominal constrictions.
Effect on dopaminergic and serotonergic system
Arulmozhi et al., (2005b) administered aqueous extract of SE at the dose of 20
and 100 mg/kg to migraine models of mice and showed significant inhibition of
apomorphine induced climbing behaviuor, l-5HT induced sertotonin syndrome and
MK-801 induced hyperactivity in mice due to its affinity towards the dopamine D2
and HT2A receptors.
Effect on central nervous system
Arulmozhi et al., (2005c) administered aqueous extract of SE at the dose of
100mg/kg to rats and showed significant reduction in thiopental induced sleep,
spontaneous locomotor activity and reduced time. SE exhibited no protection against
maximal electroshock test and pentylene tetarazole induced convulsions in mice.
Antibacterial and antifungal effect
Nair et al., (2005) reported that methanol extract of leaves of SE showed
significant antibacterial and antifungal effect against Pseudomonas, P.morgani,
Bacillus subtilius M. flavans and K. pneumonia.
Rathi et al., (2011) reported that aqueous extract of leaves of SE showed
significant antibacterial and antifungal effect aginst E.coli, S.epidermis C.glabrata
A. flavus and C. albicans.
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Antihyperglycemic and anti-diabetic activity
Jeyabalan and Muralidharan., (2009a) administered ethanolic extract of SE at
the dose of 200 and 400 mg /kg to alloxan induced diabetic rats and and showed
significant antihyperglycemic, antidiabetic and anti-hypertriglyceridemic effect.
Effect on central nervous system
Jeyabalan and Muralidharan, (2009b) reported that methanolic extract of
pericarp of SE administered at the dose of 50, 100 and 200 mg/kg to rats. SE showed
significantly potentiated the sleep induced by phenobarbitone and myorelaxant
effect.
Antihyperlipidemic activity
Methanol extract of pericarp of SE of various doses were administered to
hyperlipidemic rats. SE showed significant decrease in cholesterol and very low
density lipoproteins (VLDL) in serum Jeyabalan and Muralidharan, (2009c).
Antioxidant effect
Methanolic extract of leaves of SE posesess significant in vitro antioxidant
effect proved by DPPH scavenging methods Jeyabalan and Muralidharan, (2010).
Antiulcer activity
Kishore et al., (2010) administered methanolic and aqueous extract at the dose
of 100, 200 and 400 mg/kg to ulcer models of rats and showed significant antiulcer
effect.